Discloses is a porous separator for a fuel cell. The porous separator includes a flow plate and a flat plate. The flow plate includes a first flow surface upwardly inclined and having a first plurality of flow apertures and a second flow surface downwardly inclined and having a second plurality of f
Discloses is a porous separator for a fuel cell. The porous separator includes a flow plate and a flat plate. The flow plate includes a first flow surface upwardly inclined and having a first plurality of flow apertures and a second flow surface downwardly inclined and having a second plurality of flow apertures that are repeatedly arranged along a longitudinal direction of the flow plate. The flow plate is disposed between a gas diffusion layer of a fuel cell and a flat plate to seal the flow plate and create a flow path for hydrogen or air therein.
대표청구항▼
1. A porous separator for a fuel cell, comprising: a flow plate including a first flow surface upwardly inclined and having a first plurality of flow apertures, a second flow surface downwardly inclined and having a second plurality of flow apertures, a third flow surface upwardly inclined and conne
1. A porous separator for a fuel cell, comprising: a flow plate including a first flow surface upwardly inclined and having a first plurality of flow apertures, a second flow surface downwardly inclined and having a second plurality of flow apertures, a third flow surface upwardly inclined and connected to the second flow surface and having a third plurality of flow apertures, and a fourth flow surface downwardly inclined and connected to the third flow surface and having a plurality of fourth apertures that are repeatedly arranged along a longitudinal direction of the flow plate, and closely adhered to an outer surface of a gas diffusion layer of a fuel cell; anda flat plate coupled to an outer surface of the flow plate to seal the flow plate serving as a hydrogen or air channel,wherein first center lines of the first plurality of flow apertures formed in the first flow surface of the flow plate and the third plurality of flow apertures formed in the third flow surface of the flow plate and second center lines of the second plurality of flow apertures formed in the second flow surface of the flow plate and the fourth plurality of flow apertures formed in the fourth flow surface of the flow plate are not coincident with each other so as to be arranged in a zigzag pattern along the longitudinal direction so that reactant gases flow through the flow apertures of the first flow surface and then flows through the flow apertures of the second flow surface while diverging into a rightward and leftward flow to cause flow in a horizontal direction, andwherein the first flow surface ascends upward until the first flow surface meets the second flow surface and the third flow surface ascends upward until the third flow surface meets the fourth flow surface to form a waveform structure composed of a plurality of parabolic formations, where sloped surfaces of the parabolic formations are orthogonal to a reactant gas flow direction along the longitudinal direction of the flow plate, and the flow apertures are only formed through a side of the sloped surfaces of the parabolic formations in the longitudinal direction, such that, when reactant gases are supplied from a cathode to an anode of a fuel cell stack, reactant gas upwardly flows along the first flow surface of the flow plate, and then downwardly flow along the second flow surface a flow in a vertical direction is produced. 2. The porous separator of claim 1, wherein when a plurality of cells constituting the fuel cell are stacked on top of each other, and a gap between the flat plates of each cell serves as a cooling medium channel. 3. The porous separator of claim 1, wherein the first flow surface and the second flow surface are joined to each other to form a waveform structure. 4. The porous separator of claim 1, wherein the waveform structure is configured to create turbulence in a hydrogen flow path in one unit of a fuel cell. 5. The porous separator of claim 1, wherein the waveform structure is configured to create turbulence in an air flow path in one unit of a fuel cell. 6. The porous separator of claim 1, wherein flow plate is made of a material capable of being press molded. 7. The porous separator of claim 1, wherein the flow plate is disposed between the flat plate and a gas diffusion layer of a unit of a fuel cell. 8. A flow plate for a fuel cell separator, comprising: a flow plate includinga plurality of first flow surface upwardly inclined and a plurality of second flow surface downwardly inclined wherein each first flow surface ascends upwardly until the first flow surface meets the second flow surface to form a continuous sinusoidal shape throughout the flow path of the flow plate;a plurality of flow apertures repeatedly arranged on both the first flow surface and the second flow surface in a zigzag pattern; anda plurality of third flow surface upwardly inclined and connected to the plurality of second flow surface and having a plurality of flow apertures, and a plurality of fourth flow surface downwardly inclined and connected to the plurality of third flow surface and having a plurality of apertures,wherein the flow plate is disposed between a gas diffusion layer in the fuel cell and a flat plate to form a flow channel therein,wherein first center lines of the first plurality of flow apertures formed in the first flow surface of the flow plate and the third plurality of flow apertures formed in the third flow surface of the flow plate and second center lines of the second plurality of flow apertures formed in the second flow surface of the flow plate and the fourth plurality of flow apertures formed in the fourth flow surface of the flow plate are not coincident with each other so as to be arranged in a zigzag pattern along the longitudinal direction so that reactant gases flow through the flow apertures of the first flow surface and then flows through the flow apertures of the second flow surface while diverging into a rightward and leftward flow to cause flow in a horizontal direction, andwherein the first flow surface ascends upward until the first flow surface meets the second flow surface and the third flow surface ascends upward until the third flow surface meets the fourth flow surface to form a continuous sinusoidal shape composed of a plurality of parabolic formations in which the flow apertures are only formed through a side of sloped surfaces thereof in the longitudinal direction and the sloped surfaces are positioned orthogonal to a reactant flow direction along the longitudinal direction of the flow plate, such that, when reactant gases are supplied from a cathode to an anode of a fuel cell stack, reactant gas upwardly flows along the first flow surface of the flow plate, and then downwardly flow along the second flow surface a flow in a vertical direction is produced. 9. A fuel cell having a porous separator, comprising: a flow plate including a first flow surface upwardly inclined and having a first plurality of flow apertures, a second flow surface downwardly inclined and having a second plurality of flow apertures, a third flow surface upwardly inclined and connected to the second flow surface and having a third plurality of flow apertures, and a fourth flow surface downwardly inclined and connected to the third flow surface and having a plurality of fourth apertures that are repeatedly arranged along a longitudinal direction of the flow plate, and closely adhered to an outer surface of a gas diffusion layer of a fuel cell; anda flat plate coupled to an outer surface of the flow plate to seal the flow plate serving as a hydrogen or air channel,wherein first center lines of the first plurality of flow apertures formed in the first flow surface of the flow plate and the third plurality of flow apertures formed in the third flow surface of the flow plate and second center lines of the second plurality of flow apertures formed in the second flow surface of the flow plate and the fourth plurality of flow apertures formed in the fourth flow surface of the flow plate are not coincident with each other so as to be arranged in a zigzag pattern along the longitudinal direction so that reactant gases flow through the flow apertures of the first flow surface and then flows through the flow apertures of the second flow surface while diverging into a rightward and leftward flow to cause flow in a horizontal direction,wherein the first flow surface ascends upward until the first flow surface meets the second flow surface and the third flow surface ascends upward until the third flow surface meets the fourth flow surface to form a waveform structure composed of a plurality of parabolic formations, where sloped surfaces of the first and second flow surfaces of the parabolic formations are orthogonal to a reactant gas flow direction along the longitudinal direction of the flow plate, and the flow apertures are only formed through a side of the sloped surfaces of the first and second flow surfaces of the parabolic formations in the longitudinal direction, such that, when reactant gases are supplied from a cathode to an anode of a fuel cell stack, reactant gas upwardly flows along the first flow surface of the flow plate, and then downwardly flow along the second flow surface a flow in a vertical direction is produced,wherein a lowermost point of the waveform structure of the flow plate where the upwardly inclined first flow surface and the downwardly inclined second flow surface are joined to each other linearly contacts a gas diffusion layer of the fuel cell, andwherein an uppermost point of the waveform structure of the flow plate where the upwardly inclined first flow surface and the downwardly inclined second flow surface are joined to each other linearly contacts the flat plate to form one cell of a fuel cell stack.
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Neutzler Jay Kevin, Brazed bipolar plates for PEM fuel cells.
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